Multi-interface compatible intelligent target tracking processing terminal

The intelligent target tracking and processing terminal, with its modular layered architecture and multi-core processor, solves the problems of interface compatibility, data processing performance, and communication stability, enabling efficient acquisition and real-time processing of multi-source data, and improving the accuracy of target tracking and the interactive experience.

CN224457376UActive Publication Date: 2026-07-03BEIJING AEROSPACE TECH OLYMPIC ELECTRONICS TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING AEROSPACE TECH OLYMPIC ELECTRONICS TECH
Filing Date
2025-06-27
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing target tracking and processing terminals have shortcomings in terms of interface compatibility, data processing performance, interactive experience, and communication stability, making it difficult to meet the needs of efficient operation in complex scenarios.

Method used

The intelligent target tracking and processing terminal adopts a modular and layered architecture, integrating multiple interface modules, multi-core processors, GPU functional modules and touch screens. Combined with metal shielding design, intelligent heat dissipation system and data encryption chip, it realizes multi-source data acquisition, real-time processing and efficient interaction.

Benefits of technology

It achieves multi-interface compatibility, improved data processing speed and accuracy, enhanced interactive experience, and improved communication stability, meeting the needs of efficient target tracking in complex scenarios.

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Patent Text Reader

Abstract

This utility model discloses a multi-interface compatible intelligent target tracking and processing terminal, relating to the field of intelligent monitoring. It addresses the problems of poor interface compatibility, low tracking efficiency, weak data processing, and unsatisfactory interactive experience found in similar products. The technical solution adopted is as follows: the multi-interface compatible intelligent target tracking and processing terminal consists of a terminal body and a touch display screen. The main body contains a multi-interface module, a motherboard, an intelligent tracking module, and a GPU functional module, all of which operate collaboratively. This terminal efficiently transmits data, provides secure and flexible data processing, and offers high-definition interactive display, significantly improving the overall performance of target tracking and processing. This utility model enhances target tracking capabilities and is compatible with multiple data communication methods.
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Description

Technical Field

[0001] This utility model relates to the field of intelligent monitoring, and more specifically to an intelligent target tracking and processing terminal with multiple compatible interfaces. Background Technology

[0002] In the field of intelligent monitoring, target tracking technology is widely used in security monitoring, industrial inspection, traffic management, and other scenarios, playing a significant role in ensuring public safety and improving production efficiency. Existing target tracking processing terminals collect data through sensors, analyze target information through processors, and output results to assist users in decision-making. However, traditional terminals face many challenges in practical applications and struggle to meet the demands for efficient operation in complex scenarios.

[0003] Current target tracking and processing terminals on the market generally suffer from significant defects: In terms of interface compatibility, most devices have only one interface type, making them incompatible with new sensors such as infrared thermal imagers and high-speed cameras, thus limiting multi-source data acquisition capabilities; regarding data processing performance, traditional processors struggle to meet the demands of real-time analysis of high-resolution images, resulting in high latency in target recognition and tracking, leading to decreased tracking accuracy; in terms of user experience, ordinary displays offer poor visual effects, and the user interface is complex, making it difficult to achieve fast and accurate human-computer interaction; furthermore, communication modules have weak anti-interference capabilities, making them prone to data loss in complex electromagnetic environments, severely impacting system stability. Additionally, some terminals have inadequate heat dissipation designs, leading to performance degradation over extended periods of operation.

[0004] This utility model proposes a multi-interface compatible intelligent target tracking and processing terminal. Addressing the aforementioned technical bottlenecks, it achieves a technological breakthrough through innovative structural design and functional module optimization. The terminal consists of a main body and a touch display screen. The main body integrates a multi-interface module, a motherboard, the intelligent tracking module, and a GPU functional module, all working collaboratively. The main body adopts a modular, layered architecture, with a high-strength aluminum alloy frame and an efficient heat dissipation system to ensure stable operation. The multi-interface module integrates various professional interfaces, and its metal shielding design enables high-speed transmission of multi-source data. The intelligent tracking module collaborates with a multi-core processor and hardware acceleration unit to ensure secure and efficient data processing. The motherboard features a modular design with powerful computing and storage capabilities. The GPU functional module's units work closely together to optimize the entire process of image reception and target recognition. The touch display screen uses OLED technology and an ergonomic design to achieve high-definition interactive display. This terminal provides an efficient and reliable solution for target tracking in complex scenarios, possessing significant technical value and application prospects. Utility Model Content

[0005] The purpose of this invention is to realize a multi-interface compatible intelligent target tracking and processing terminal with a wide detection range, high data acquisition accuracy, strong environmental adaptability, and high degree of intelligence.

[0006] To achieve the above-mentioned technical effects, the present invention adopts the following technical solution:

[0007] A multi-interface compatible intelligent target tracking processing terminal includes a terminal body and a touch screen display. The touch screen display is connected to the terminal body below via a bracket. The front of the terminal body is equipped with a multi-interface module, and the interior houses a motherboard, the intelligent tracking module, and a GPU function module. The signal output terminal of the intelligent tracking module is connected to the signal input terminal of the GPU function module. The GPU function module and the motherboard are bidirectionally connected. The multi-interface module and the motherboard are bidirectionally connected. The touch screen display and the high-definition motherboard are bidirectionally connected.

[0008] As a further description of the above technical solution:

[0009] The mechanical structure of the terminal body adopts a modular and layered architecture, with high-strength aluminum alloy as the main frame, including a core processing area, an interface connection area, a power management area, and a heat dissipation area. The core processing area is equipped with key electronic components and a heat dissipation device. The interface connection area integrates multiple interfaces and features a detachable panel design for easy expansion. The power management area is equipped with a power module and protection circuits. The heat dissipation area utilizes heat dissipation holes and an intelligent fan for cooling.

[0010] As a further description of the above technical solution:

[0011] The multi-interface module includes an infrared thermal imager interface, a visible light camera interface, a turntable interface, a host computer interface, a video output interface, a servo mechanism interface, and a power interface; each interface adopts a metal shielding design, which can effectively reduce electromagnetic interference; the infrared thermal imager interface, visible light camera interface, turntable interface, host computer interface, video output interface, servo mechanism interface, and power interface are bidirectionally connected to the motherboard signal.

[0012] As a further description of the above technical solution:

[0013] The intelligent tracking module includes an intelligent computing processor, an intelligent interrupt controller, an intelligent network controller, a dedicated hardware acceleration unit, a data encryption chip, and multiple input / output interfaces. The intelligent computing processor is bidirectionally connected to the intelligent interrupt controller, intelligent network controller, dedicated hardware acceleration unit, data encryption chip, and multiple input / output interfaces. As the core, the intelligent computing processor uses a multi-core high-performance chip to coordinate the work of each component and ensure the overall stable operation of the module. The intelligent interrupt controller monitors the system in real time and can quickly respond and send an interrupt request to the processor when an abnormal event occurs, ensuring that the system can handle emergencies in a timely manner and improving the reliability and stability of the system. The intelligent network controller supports multiple network protocols and can automatically switch connection methods according to the network environment. The dedicated hardware acceleration unit is designed for specific computing tasks. The data encryption chip encrypts transmitted and stored data to prevent data leakage and ensure information security. The multiple input / output interfaces enable flexible data input and output.

[0014] As a further description of the above technical solution:

[0015] The motherboard is the core component of a multi-interface compatible intelligent target tracking and processing terminal. It adopts a modular design and is assembled from a core circuit board and expansion circuit boards through high-speed slots. It has powerful computing, graphics processing, and data storage capabilities, including a CPU module, graphics card, high-speed connector, heat dissipation module, platform management chip, BIOS chip, debug interface, and large-capacity storage module. The CPU module is bidirectionally connected to the graphics card, high-speed connector, heat dissipation module, platform management chip, BIOS chip, debug interface, and large-capacity storage module.

[0016] As a further description of the above technical solution:

[0017] The GPU functional module includes an image receiving unit, a communication unit, a target recognition and tracking unit, an information loading unit, and a device self-test unit. The signal output terminal of the image receiving unit is connected to the signal input terminals of the target recognition and tracking units, providing them with image data that has been preliminarily parsed and cached. The communication unit is bidirectionally connected to the target recognition and tracking units, and can receive external control commands for target recognition and tracking, and send the processing results of the target position and category obtained from target recognition and tracking to external devices. The information loading unit is bidirectionally connected to the target recognition and tracking units, and loads the correctly configured software parameters into the GPU memory required for the target recognition and tracking units to ensure that the target recognition and tracking functions can work according to different application scenarios. The device self-test unit is bidirectionally connected to the image receiving, communication, target recognition and tracking, and information loading units. When the system starts, the device self-test module performs an integrity check on the GPU hardware status, loaded database models, and parameters required for the operation of these modules. If an anomaly is detected, it will report back to each unit and take corresponding processing measures.

[0018] As a further description of the above technical solution:

[0019] The touch display screen consists of a display panel, a circuit board, an anti-glare protective glass, and an adjustable outer frame bracket; the display panel uses an OLED display; the circuit board includes an image control circuit board and a pixel driving circuit board, located below the display panel; the anti-glare protective glass covers the display panel; the adjustable outer frame bracket is made of high-strength alloy material; the touch display screen is equipped with a compatible interface, connects to the motherboard, and can receive video signals from external devices to achieve high-definition display of multi-source data.

[0020] This utility model's multi-interface compatible intelligent target tracking and processing terminal, through the innovative design and collaborative work of its various modules, achieves multi-dimensional technological breakthroughs and possesses significant positive and beneficial effects:

[0021] The multi-interface module integrates multiple interfaces such as infrared thermal imagers and visible light cameras. Its metal shielding design reduces electromagnetic interference, enabling compatibility with multi-source data acquisition devices. The detachable panel facilitates future functional expansion, solving the problems of traditional terminals' single interface and poor compatibility, and meeting the access needs of various types of devices in complex scenarios. The intelligent tracking module uses a multi-core high-performance chip and dedicated hardware acceleration unit. Combined with the powerful image reception, target recognition, and tracking capabilities of the GPU module, it can achieve real-time processing of high-resolution images, significantly improving the speed and accuracy of target recognition and tracking, effectively reducing processing latency, and handling complex computational tasks involving massive amounts of data. The terminal's modular layered architecture, coupled with a high-strength aluminum alloy frame, a heat dissipation device in the core processing area, protection circuits in the power management area, and an intelligent heat dissipation design in the heat dissipation area, ensures stable operation of internal components. The intelligent interrupt controller monitors anomalies in real time, and the device self-test unit performs a comprehensive check during startup, significantly improving system reliability and stability. The data encryption chip encrypts transmitted and stored data. Combined with the multi-protocol support and adaptive switching function of the intelligent network controller, it ensures secure data transmission in complex network environments, prevents information leakage, and provides reliable protection for data security.

[0022] Superior human-computer interaction experience: The touch screen uses OLED display technology, which, together with the circuit board, enables precise image control. The anti-glare protective glass improves visibility, the adjustable frame stand is ergonomic, and the compatible interface enables high-definition display of multi-source data. The operation is convenient and intuitive, significantly improving the human-computer interaction experience. Attached Figure Description

[0023] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort, wherein:

[0024] Figure 1 This is an overall structural diagram of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0025] Figure 2 This is an overall flowchart of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0026] Figure 3 This is the host computer interface circuit diagram of the multi-interface compatible intelligent target tracking and processing terminal of this utility model.

[0027] Figure 4 This is a circuit diagram of the video output interface of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0028] Figure 5 A power supply schematic diagram of an exemplary embodiment of the power supply module of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0029] Figure 6 A power supply schematic diagram of an exemplary embodiment of the multi-interface module of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0030] Figure 7 A power supply schematic diagram of another exemplary embodiment of the multi-interface module of the multi-interface compatible intelligent target tracking and processing terminal of this utility model;

[0031] Figure 8 A power supply schematic diagram of an exemplary embodiment of the GPU functional module of the multi-interface compatible intelligent target tracking processing terminal of this utility model;

[0032] In the diagram: Terminal main body-1, Touch screen display-2, Motherboard-3, Multi-interface module-4, Intelligent tracking module-5, GPU function module-6. Detailed Implementation

[0033] The preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the embodiments described herein are for illustration and explanation only and are not intended to limit the present invention.

[0034] To achieve the above-mentioned technical effects, the present invention adopts the following technical solution:

[0035] like Figures 1-8 As shown, a multi-interface compatible intelligent target tracking processing terminal includes a terminal body 1 and a touch screen display 2. The touch screen display 2 is connected to the terminal body 1 below via a bracket. The front of the terminal body 1 is provided with a multi-interface module 4, and the interior is provided with a motherboard 3, an intelligent tracking module 5, and a GPU function module 6. The signal output terminal of the intelligent tracking module 5 is connected to the signal input terminal of the GPU function module 6. The GPU function module 6 and the motherboard 3 are bidirectionally connected. The multi-interface module 4 and the motherboard 3 are bidirectionally connected. The touch screen display 2 and the high-definition motherboard 3 are bidirectionally connected.

[0036] This invention optimizes the design of a multi-interface compatible intelligent target tracking and processing terminal from multiple aspects, specifically addressing the technical challenges of poor interface compatibility, low processing efficiency, and weak data security in existing target tracking devices, thereby achieving efficient, accurate, and secure target tracking operations.

[0037] Specific embodiments are shown below:

[0038] I. Solving the problem of poor interface compatibility

[0039] This utility model's multi-interface module 4 integrates multiple professional interfaces, including an infrared thermal imager interface and a visible light camera interface, and adopts a metal shielding design. In practical applications, when it is necessary to connect to an infrared thermal imager for target temperature monitoring, the infrared thermal imager interface can be directly connected to the thermal imager. The metal shielding layer effectively resists external electromagnetic interference, ensuring distortion-free transmission of high-definition thermal imaging data at up to 100 frames per second. For visible light cameras of different specifications, the visible light camera interface supports various resolutions and frame rates of video streaming protocols, such as MJPEG and H.264, and can quickly adapt to and stably transmit 4K 60Hz video data. For external devices such as turntables and servo mechanisms, the corresponding interfaces can accurately transmit control commands and feedback data, achieving seamless interoperability between devices and completely solving the problem of traditional terminal interfaces being single and difficult to adapt to multiple types of devices.

[0040] II. Solutions to the Problem of Low Target Tracking Efficiency

[0041] The intelligent tracking module 5 and GPU module 6 work together to improve processing efficiency. The intelligent computing processor uses a multi-core high-performance chip. When the terminal receives image data, the intelligent computing processor immediately coordinates the work of each component, quickly distributing the data to the dedicated hardware acceleration unit and GPU module 6. The dedicated hardware acceleration unit accelerates tasks such as convolution operations in the target tracking algorithm, achieving a processing speed of up to 10 trillion operations per second. The target recognition and tracking unit of GPU module 6 uses the YOLOv5 algorithm, combined with its 275 TOPS AI computing power, and can complete the recognition and tracking of multiple targets in a 1080P image within 200ms, which is more than 5 times faster than traditional devices. Simultaneously, the intelligent interrupt controller monitors the system in real time. When anomalies such as sudden target loss occur, it can respond within 1ms and send a request to the processor to adjust the tracking strategy in a timely manner, ensuring the continuity and accuracy of target tracking.

[0042] III. Solutions to the Problem of Insufficient Data Processing Capacity

[0043] The motherboard 3 adopts a modular design, with the core circuit board and expansion circuit boards connected via high-speed slots. The CPU module and graphics card work closely together. When processing large amounts of image data in complex scenes, the CPU module is responsible for logical operations and task scheduling, while the graphics card focuses on image rendering and accelerated processing. For example, when processing multiple 4K video streams captured simultaneously by multiple cameras, the high-speed connector supports the PCIe 4.0 protocol, achieving bidirectional data transfer speeds of 20GB / s, ensuring bottleneck-free data interaction between components. The cooling module combines a vapor chamber and a turbine fan. When the motherboard load reaches 80%, the intelligent fan automatically speeds up, keeping the CPU and graphics card temperatures below 75℃, ensuring no performance degradation during prolonged high-load operation and meeting the needs of processing large amounts of data with high complexity.

[0044] IV. Solutions to Data Security Risks

[0045] Data encryption chips and intelligent network controllers ensure secure data transmission. The data encryption chip uses the AES-256 encryption algorithm to encrypt data before transmission, achieving an encryption speed of up to 1GB per second. The intelligent network controller supports multiple network protocols and can automatically switch between Ethernet and 5G networks in complex network environments, such as industrial sites with strong electromagnetic interference. When a network attack is detected, the intelligent network controller immediately activates its firewall mechanism to block unauthorized access and simultaneously performs integrity verification on the transmitted data, ensuring that data is not stolen or tampered with during transmission and storage. Compared to traditional equipment, its data security protection capability is improved by more than 80%.

[0046] V. Solutions to Poor Human-Computer Interaction Experience

[0047] The touchscreen display 2 utilizes OLED display technology and an ergonomic design. The display panel boasts a pixel density of 400 PPI, clearly displaying target details when tracking images. The image control circuit board optimizes the input video signal in real time, while the pixel drive circuit board precisely controls the illumination of each pixel, resulting in a color reproduction accuracy of up to 98%. The anti-glare protective glass reduces ambient light reflectivity to below 1% in strong light environments, ensuring clear visibility. The adjustable frame supports multi-angle adjustment from 0-90°, allowing users to adjust the display angle according to their usage scenarios and personal preferences. Furthermore, the touch operation response time is less than 5ms, supporting multi-touch. Users can quickly perform operations such as zooming and target selection by touching the screen, improving interaction efficiency by 60% compared to traditional devices and delivering a superior human-computer interaction experience.

[0048] Furthermore, the mechanical structure of the terminal body 1 adopts a modular and layered architecture, with high-strength aluminum alloy as the main frame, including a core processing area, an interface connection area, a power management area, and a heat dissipation area. The core processing area is equipped with key electronic components and a heat dissipation device. The interface connection area integrates multiple interfaces and features a detachable panel design for easy expansion. The power management area is equipped with a power module and protection circuit. The heat dissipation area utilizes heat dissipation holes and an intelligent fan for heat dissipation.

[0049] In a specific embodiment, the technical essence of the mechanical structure of the terminal body 1 lies in its modular and layered architecture design. Using high-strength aluminum alloy as the main frame, it constructs four functional modules: a core processing area, an interface connection area, a power management area, and a heat dissipation area. The principle is to achieve independent optimization and collaborative work of each module through functional zoning: the core processing area centrally arranges key electronic components and is equipped with a heat dissipation device, providing a stable operating environment for core components such as the motherboard and intelligent tracking module, avoiding performance degradation due to mutual interference between components; the interface connection area uses a detachable panel to integrate multiple interfaces, utilizing standardized design to achieve rapid docking with external devices. When functional expansion is needed, new interfaces can be connected by replacing the panel, improving device adaptability; the power management area is equipped with a power module and protection circuits to achieve stable power supply and protection against overcurrent, overvoltage, and other abnormalities, ensuring the reliability of the terminal's power supply; the heat dissipation area utilizes heat dissipation holes and an intelligent fan. Based on the principle of thermal convection, the intelligent fan automatically adjusts its speed according to temperature sensor feedback, promptly dissipating the heat generated in the core processing area and preventing performance degradation or component damage due to overheating. This results in significant benefits: the high-strength aluminum alloy frame provides the terminal with excellent mechanical strength and protective performance, capable of withstanding certain external impacts and meeting the needs of complex application scenarios; the modular design allows each functional module to be maintained and upgraded independently, reducing equipment maintenance costs and difficulty, and extending service life; the layered architecture optimizes the internal space layout, reduces electromagnetic interference, and improves system stability; the detachable panel's interface connection area greatly enhances the device's expandability, adapting to different stages of technological development and application needs; the power management area's protection circuit effectively avoids damage to the equipment caused by power anomalies, ensuring data security and stable system operation; the intelligent heat dissipation system ensures that the terminal maintains stable performance even under long-term high-load operation, avoiding calculation errors or equipment failures caused by overheating, comprehensively improving the terminal's reliability, adaptability, and service life, and providing a solid hardware foundation for efficient target tracking processing.

[0050] Furthermore, the multi-interface module 4 includes an infrared thermal imager interface, a visible light camera interface, a turntable interface, a host computer interface, a video output interface, a servo mechanism interface, and a power interface; each interface adopts a metal shielding design, which can effectively reduce electromagnetic interference; the infrared thermal imager interface, visible light camera interface, turntable interface, host computer interface, video output interface, servo mechanism interface, and power interface are bidirectionally connected to the motherboard 3.

[0051] In a specific embodiment, the multi-interface module 4 essentially integrates multiple compatible interfaces and employs a metal shielding design to achieve data interaction, control command transmission, and power supply functions between the terminal and external devices. It also connects to the motherboard 3 to construct a complete data processing link. The principle is that each compatible interface is specifically designed according to the communication protocol and electrical characteristics of its corresponding device. For example, the infrared thermal imager interface adapts to thermal imaging data transmission protocols, and the visible light camera interface supports high-resolution video stream transmission standards, ensuring accurate data access and output from different devices. The turntable interface and servo mechanism interface achieve precise control command transmission to external mechanical devices through specific signal protocols. The metal shielding design utilizes the principle of electromagnetic shielding, forming a Faraday cage through a metal casing to shield external electromagnetic interference signals from the interface, preventing interference and distortion of transmitted data. Each interface connects to the motherboard 3, leveraging the motherboard's data processing and transmission capabilities to achieve centralized data processing, distribution, and the parsing and execution of control commands. Its beneficial effects are significant: the integration of multiple compatible interfaces enables the terminal to be compatible with various types of devices such as infrared thermal imagers and visible light cameras, meeting the needs of multi-source data acquisition and device control in complex scenarios, and greatly expanding the application range of the terminal; the metal shielding design effectively reduces electromagnetic interference, ensuring the accuracy and stability of data during transmission, avoiding data loss, errors, or device malfunctions caused by interference, and improving system reliability; the connection between each interface and the motherboard 3 realizes efficient data flow from acquisition, transmission to processing, ensuring that the terminal can quickly respond to external device data, process and output results in real time, and improve the efficiency and accuracy of target tracking processing; the power interface provides a stable power supply for external devices, reduces the need for additional power configuration, simplifies the system architecture, and ensures the normal operation of devices without external power, enhancing the overall practicality and convenience of the terminal.

[0052] Furthermore, the intelligent tracking module 5 includes an intelligent computing processor, an intelligent interrupt controller, an intelligent network controller, a dedicated hardware acceleration unit, a data encryption chip, and multiple input / output interfaces. The intelligent computing processor is bidirectionally connected to the intelligent interrupt controller, the intelligent network controller, the dedicated hardware acceleration unit, the data encryption chip, and the multiple input / output interfaces. The intelligent computing processor, as the core, uses a multi-core high-performance chip to coordinate the work of each component and ensure the overall stable operation of the module. The intelligent interrupt controller monitors the system in real time and can quickly respond and send an interrupt request to the processor when an abnormal event occurs, ensuring that the system can handle emergencies in a timely manner and improving the reliability and stability of the system. The intelligent network controller supports multiple network protocols and can automatically switch connection methods according to the network environment. The dedicated hardware acceleration unit is designed for specific computing tasks. The data encryption chip encrypts transmitted and stored data to prevent data leakage and ensure information security. The multiple input / output interfaces enable flexible data input and output.

[0053] In specific embodiments, the intelligent computing processor employs multi-core CPUs: Intel Xeon series (server-grade multi-core processing), ARM Cortex-A57 / A72 (embedded high performance); GPUs: NVIDIA Jetson AGX Xavier (edge ​​AI computing), AMD Radeon Pro series (parallel computing); FPGAs: Xilinx UltraScale+ (reconfigurable computing); and ASICs: custom chips (such as Huawei Ascend series AI chips). As the core of the module, it coordinates data flow and task scheduling. The multi-core architecture supports parallel processing, improving real-time computing capabilities. It communicates with other components via buses (such as PCIe, AXI).

[0054] In this specific embodiment, the intelligent interrupt controller employs the PLX Technology PEX 8700 series (PCIe interrupt controller). It can monitor the status of various system components, detect abnormal events (such as sensor data exceeding limits or network packet loss), implement interrupt priority management, and ensure that critical events are handled first. It can quickly wake up the processor via hardware signals (such as IRQ and NMI).

[0055] The intelligent network controller uses the Qualcomm QCA6574 (Wi-Fi 6 + Bluetooth 5.0) and Marvell AQtion series (10G / 25G Ethernet controller), supporting multiple protocol stacks (TCP / IP, UDP, MQTT, CoAP) and enabling adaptive network switching (such as seamless switching from 4G to Wi-Fi). It features built-in hardware acceleration (such as TCP segmentation offloading and encryption acceleration). A dedicated hardware acceleration unit works in conjunction with the main processor to form a heterogeneous computing architecture.

[0056] The data encryption chip uses the Microchip CryptoAuthentication series (ATECC608A).

[0057] The NXP SE050 (Secure Element, supports SEEPROM) enables encryption using AES-256, RSA-4096, and ECC. It features a built-in True Random Number Generator (TRNG) supporting secure key storage and management (key isolation, protection against physical attacks). Input / output interfaces are compatible with USB, CAN FD (Microchip MCP2517FD controller), Siemens SPC3 controller (via Profibus), and sensor interfaces such as SPI (TI SN65HVD3082E, RS-485 to SPI) and I²C (NXP PCA9685, 16-channel PWM controller). It facilitates data transmission between different devices through protocol conversion, supports data buffering and flow control mechanisms (such as FIFO buffers), and provides electrical isolation (such as optocoupler-isolated RS-232 interfaces).

[0058] In a specific embodiment, the technical essence of the intelligent tracking module 5 is to construct a multi-component collaborative architecture with an intelligent computing processor at its core, achieving efficient target tracking and data processing through the division of labor and cooperation among various functional units. Its principle is as follows: the intelligent computing processor uses a multi-core high-performance chip, based on the principle of parallel computing, and is connected to components such as the intelligent interrupt controller and intelligent network controller through an internal bus to coordinate and schedule data processing and task allocation; the intelligent interrupt controller monitors the system's operating status in real time, and based on an interrupt priority mechanism, immediately sends an interrupt signal to the intelligent computing processor when events such as target loss or data anomalies occur, suspending the current task and handling the emergency; the intelligent network controller has a built-in protocol stack that can identify the strength and quality of network signals such as Wi-Fi, 4G / 5G, etc., and automatically switches to the optimal network connection method according to a preset algorithm; the dedicated hardware acceleration unit uses FPGA or ASIC technology to accelerate the processing of tasks such as convolution and matrix operations in the target tracking algorithm through parallel computing of hardware circuits; the data encryption chip uses encryption algorithms such as AES and RSA to encrypt and decrypt input and output data; multiple input and output interfaces follow standard protocols such as USB and Ethernet to achieve bidirectional data transmission and device connection. The module delivers significant benefits: the multi-core high-performance intelligent computing processor significantly improves data processing efficiency, ensuring the real-time performance of the target tracking algorithm; the intelligent interrupt controller enables the system to respond quickly to anomalies, effectively reducing the risk of task interruption due to unforeseen circumstances and enhancing system stability; the intelligent network controller ensures the continuity and stability of data transmission in complex network environments, improving device adaptability; the dedicated hardware acceleration unit drastically shortens algorithm computation time, improving efficiency several times compared to pure software processing; the data encryption chip constructs a security barrier for data transmission and storage, preventing the leakage of sensitive information and meeting the needs of high-security scenarios; diverse input / output interfaces support multi-source data access and output, adapting to different types of sensors and display devices, greatly expanding the module's application scope, and ultimately achieving accurate, efficient, and secure target tracking functions, providing core technical support for intelligent terminals.

[0059] Furthermore, the motherboard 3 is the core component of a multi-interface compatible intelligent target tracking processing terminal. It adopts a modular design and is composed of a core circuit board and an expansion circuit board spliced ​​together by high-speed slots. It has powerful computing, graphics processing and data storage capabilities, including a CPU module, a graphics card, a high-speed connector, a heat dissipation module, a platform management chip, a BIOS chip, a debug interface and a large-capacity storage module. The CPU module is bidirectionally connected to the graphics card, the high-speed connector, the heat dissipation module, the platform management chip, the BIOS chip, the debug interface and the large-capacity storage module.

[0060] In a specific embodiment, the core technology of motherboard 3 is a modular design that connects the core circuit board and expansion circuit boards via high-speed slots to construct a core processing architecture integrating multiple functional components. The principle is that the core circuit board houses key components such as the CPU module, platform management chip, and BIOS chip. The CPU module, as the computing core, connects to components such as the graphics card and high-speed connectors via a data bus, performing data processing and instruction scheduling. The platform management chip monitors the operating parameters of each component on the motherboard in real time, such as temperature and voltage, and adjusts the cooling module and power supply through a feedback mechanism. The BIOS chip stores the system startup and hardware initialization programs, guiding the system loading during boot. The expansion circuit boards provide additional functional expansion, and both achieve high-speed data transmission via high-speed slots. The high-speed connectors use standard protocols such as PCIe 4.0 and USB 3.2 to ensure data transmission rates between components. The cooling module consists of heat sinks, heat pipes, and intelligent fans, rapidly dissipating heat generated by the CPU and graphics card through heat conduction and convection. The large-capacity storage module uses NVMe protocol solid-state drives to achieve high-speed data read and write. The resulting benefits include: modular design provides the motherboard with high flexibility, allowing users to choose expansion circuit boards to customize and upgrade functions, reducing equipment upgrade costs; high-speed slots and connectors ensure low latency and high bandwidth data transmission between components, meeting the real-time data processing needs of multi-interface modules; the CPU module and graphics card work together to significantly improve the calculation speed of target tracking algorithms and image rendering capabilities, enabling real-time processing of multiple high-definition video streams; the platform management chip and intelligent heat dissipation module combine to achieve intelligent adjustment of the motherboard's operating status, keeping the CPU temperature below 75°C under high load, ensuring long-term stable system operation; large-capacity storage modules provide ample data storage space, and with high-speed read and write performance, can quickly store processed target tracking data; the debugging interface facilitates technicians to diagnose motherboard faults and optimize performance; the BIOS chip ensures stable system startup, improving overall terminal processing efficiency, stability, and scalability.

[0061] Furthermore, the GPU functional module 6 includes an image receiving unit, a communication unit, a target recognition and tracking unit, an information loading unit, and a device self-test unit. The signal output terminal of the image receiving unit is connected to the signal input terminals of the target recognition and tracking units, providing them with image data that has been preliminarily parsed and cached. The communication unit is bidirectionally connected to the target recognition and tracking units, and can receive external control commands for target recognition and tracking, and send the processing results of the target position and category obtained from target recognition and tracking to external devices. The information loading unit is bidirectionally connected to the target recognition and tracking units, and loads the correctly configured software parameters into the GPU memory required for the target recognition and tracking units to ensure that the target recognition and tracking functions can work according to different application scenarios. The device self-test unit is bidirectionally connected to the image receiving, communication, target recognition and tracking, and information loading units. When the system starts, the device self-test module performs an integrity check on the GPU hardware status, loaded database models, and parameters required for the operation of these modules. If an anomaly is detected, it will report back to each unit and take corresponding processing measures.

[0062] The specific embodiment of GPU functional module 6 uses the LTM4644 core chip, which is typically used in GPU systems to provide stable power to core components. Based on your description of GPU functional module 6, the following is an analysis of the technical principles of each unit and the role of the LTM4644 within it:

[0063] The image receiving unit supports high-speed image data transmission protocols (such as Camera Link, GigE Vision, and CoaXPress), and its data cache has built-in FIFO or DDR memory with a cache rate of over 10GB / s. Format conversion transforms RAW image data into GPU-supported formats (such as RGBA and YUV420). Synchronization processing achieves timestamp alignment and frame synchronization of data from multiple cameras.

[0064] The LTM4644 circuitry provides multiple regulated power supplies (typical: 1.2V core voltage, 3.3V I / O voltage) for the high-speed SerDes interface and buffer chip of the image receiver unit, and supports dynamic voltage regulation to optimize power consumption.

[0065] Communication unit protocol support: Control command reception: Supports protocols such as SPI, I2C, and Ethernet; supports high-speed interfaces such as Gigabit Ethernet and PCIe Gen3; data encapsulation packages the identification results into standard formats (such as JSON and Protobuf). Priority queues are implemented through a QoS mechanism to ensure that critical commands are processed first. Low-noise power is provided to communication controllers (such as Ethernet PHYs and PCIe bridges) to ensure signal integrity. Its built-in EMI filtering function reduces interference to high-speed communication signals.

[0066] The target recognition and tracking unit utilizes parallel computing models based on CUDA or OpenCL to achieve efficient allocation of GPU memory (such as a unified memory architecture), supporting batch processing to improve throughput. It provides up to 30A of continuous power to the GPU core and supports load line compensation to handle sudden computational demands. Its multi-phase parallel technology reduces power ripple and ensures the accuracy of floating-point operations.

[0067] In a specific embodiment, the technical essence of GPU functional module 6 lies in constructing a functional system with clear division of labor and close collaboration. Through the organic combination of an image receiving unit, a communication unit, a target recognition and tracking unit, an information loading unit, and a device self-testing unit, efficient image data processing and target tracking are achieved. The principle is as follows: the image receiving unit uses the GPU's high-bandwidth data interface to receive data from the image acquisition device. After initial parsing and caching by the driver, the data is transmitted to the target recognition and tracking unit in the form of a data stream. The communication unit establishes a data interaction channel with external devices based on network communication protocols, receives control commands, and sends processing results. The target recognition and tracking unit relies on the GPU's powerful parallel computing capabilities to run deep learning algorithms for real-time processing of the input image data. The information loading unit accurately loads software parameters adapted to different application scenarios into the GPU's video memory through the GPU driver interface, providing operating parameters for the target recognition and tracking unit. At system startup, the device self-testing unit performs a comprehensive scan of the GPU hardware status and database model parameters according to preset detection rules, ensuring that the operating conditions of each unit meet the standards through a feedback mechanism. This module delivers significant benefits: the efficient integration of the image receiving unit and the target recognition and tracking unit enables seamless data flow from acquisition to processing, greatly improving data processing timeliness; the communication unit ensures stable data interaction between the module and external devices, enabling timely control commands and real-time feedback of processing results, enhancing system responsiveness; the information loading unit can dynamically adjust operating parameters according to different scenario requirements, significantly improving the accuracy and flexibility of target recognition and tracking; the device self-test unit eliminates potential faults during system startup, preventing operational anomalies due to hardware or software issues and reducing system failure rate; the collaborative operation of each unit fully leverages the advantages of GPU parallel computing, improving target recognition and tracking efficiency several times over in complex scenarios compared to traditional processing methods, providing powerful data processing and analysis capabilities for multi-interface compatible intelligent target tracking processing terminals, ensuring stable and efficient operation of the terminal in various application scenarios. The GPU's data matching process is shown in Table 1.

[0068]

[0069] Furthermore, the touch display screen 2 is composed of a display panel, a circuit board, an anti-glare protective glass, and an adjustable outer frame bracket; the display panel adopts an OLED display; the circuit board includes an image control circuit board and a pixel driving circuit board, located below the display panel; the anti-glare protective glass covers the display panel; the adjustable outer frame bracket is made of high-strength alloy material; the touch display screen 2 is equipped with a compatible interface, connected to the motherboard 3, and can receive video signals from external devices to achieve high-definition display of multi-source data.

[0070] In a specific embodiment, the technical essence of the touch display screen 2 is to organically integrate components such as the display panel, circuit board, anti-glare protective glass, and adjustable outer frame bracket to construct a human-computer interaction terminal with high-definition display, precise touch, and flexible adjustment functions, and to achieve data communication with the motherboard 3 through a compatible interface. The principle is that the display panel using OLED display technology is based on self-emissive characteristics, and each pixel can independently control its light emission, presenting images through changes in pixel brightness and color; the image control circuit board in the circuit board decodes, optimizes, and converts the input video signal to ensure image quality, while the pixel drive circuit board precisely controls the light intensity and color of each pixel to achieve a delicate display effect; the anti-glare protective glass reduces surface reflectivity through a special optical coating, reducing interference from ambient light on the display screen; the adjustable outer frame bracket utilizes the structural strength of a high-strength alloy, and achieves multi-angle adjustment of the display screen through mechanical hinges and damping devices; the compatible interface follows a standardized communication protocol to achieve data transmission with the motherboard 3, converting the processed video signal into a drive signal recognizable by the display screen. The resulting benefits are as follows: OLED display technology endows the display with high contrast, wide viewing angle, and fast response, clearly presenting details of target tracking images with a color reproduction accuracy of over 98%; the dual circuit design of the circuit board ensures the stability and accuracy of image display, avoiding problems such as image delay and distortion; the anti-glare protective glass reduces ambient light reflectivity to below 1%, ensuring clear visibility of the display even under direct sunlight, improving its applicability in complex lighting environments; the adjustable frame supports free adjustment from 0-90° to meet the needs of different usage scenarios and user viewing angles, conforming to ergonomic design; the compatible interface and connection with the motherboard 3 enable high-speed transmission of multi-source data, supporting 4K@60Hz ultra-high-definition video signal display, and with the touch function, users can retrieve and zoom in on target information in real time through touch operation, with an interaction response time of less than 5ms, significantly improving human-computer interaction efficiency and operating experience, and providing an intuitive and convenient visual interface for intelligent target tracking processing.

[0071] While specific embodiments of this utility model have been described above, those skilled in the art should understand that these specific embodiments are merely illustrative. Those skilled in the art can omit, substitute, and modify the details of the above methods and systems in various ways without departing from the principles and essence of this utility model. For example, combining the above method steps to perform substantially the same function and achieve substantially the same result according to substantially the same method falls within the scope of this utility model. Therefore, the scope of this utility model is defined only by the appended claims.

Claims

1. A multi-interface compatible intelligent target tracking and processing terminal, characterized in that: The device includes a terminal body (1) and a touch screen (2), the touch screen (2) being connected to the terminal body (1) below via a bracket; the terminal body (1) has a multi-interface module (4) on its front, and a motherboard (3), an intelligent tracking module (5), and a GPU function module (6) are arranged inside the terminal body (1); the signal output terminal of the intelligent tracking module (5) is connected to the signal input terminal of the GPU function module (6); the GPU function module (6) is bidirectionally connected to the motherboard (3); the multi-interface module (4) is bidirectionally connected to the motherboard (3); and the touch screen (2) is bidirectionally connected to the motherboard (3).

2. The multi-interface compatible intelligent target tracking processing terminal according to claim 1, characterized in that: The mechanical structure of the terminal body (1) adopts a modular and layered architecture. The terminal body (1) includes a core processing area, an interface connection area, a power management area, and a heat dissipation area. The core processing area is equipped with key electronic components and a heat dissipation device. The interface connection area integrates multiple interfaces and has a detachable panel design for easy expansion. The power management area is equipped with a power module and a protection circuit. The heat dissipation area utilizes heat dissipation holes and an intelligent fan for cooling.

3. The multi-interface compatible intelligent target tracking processing terminal of claim 1, wherein: The multi-interface module (4) includes an infrared thermal imager interface, a visible light camera interface, a turntable interface, a host computer interface, a video output interface, a servo mechanism interface, and a power interface; each interface adopts a metal shielding design, which can effectively reduce electromagnetic interference; the infrared thermal imager interface, visible light camera interface, turntable interface, host computer interface, video output interface, servo mechanism interface, and power interface are bidirectionally connected to the motherboard (3).

4. The multi-interface compatible smart target tracking processing terminal of claim 1, wherein: The intelligent tracking module (5) includes an intelligent computing processor, an intelligent interrupt controller, an intelligent network controller, a dedicated hardware acceleration unit, a data encryption chip, and various input / output interfaces; the intelligent computing processor is bidirectionally connected to the intelligent interrupt controller, the intelligent network controller, the dedicated hardware acceleration unit, the data encryption chip, and various input / output interfaces.

5. The multi-interface compatible intelligent target tracking processing terminal of claim 1, wherein: The motherboard (3) consists of the core components of a multi-interface compatible intelligent target tracking processing terminal, including a CPU module, a graphics card, a high-speed connector, a heat dissipation module, a platform management chip, a BIOS chip, a debugging interface, and a large-capacity storage module; the CPU module is bidirectionally connected to the graphics card, the high-speed connector, the heat dissipation module, the platform management chip, the BIOS chip, the debugging interface, and the large-capacity storage module.

6. The multi-interface compatible intelligent target tracking processing terminal of claim 1, wherein: The GPU functional module (6) includes an image receiving unit, a communication unit, a target recognition and tracking unit, an information loading unit, and a device self-testing unit. The signal output terminal of the image receiving unit is connected to the signal input terminals of the target recognition unit and the tracking unit, providing them with image data that has been preliminarily parsed and cached. The communication unit is bidirectionally connected to the target recognition unit and the tracking unit. The communication unit can receive external control commands for target recognition and tracking, and send the processing results of the target position and category obtained from target recognition and tracking to external devices. The information loading unit is bidirectionally connected to the target recognition unit and the tracking unit. The information loading unit loads the correctly configured software parameters into the GPU video memory required for the target recognition and tracking unit to ensure that the target recognition and tracking function can work according to different application scenarios. The device self-testing unit is bidirectionally connected to the image receiving, communication, target recognition and tracking, and information loading units. When the system starts, the device self-testing module performs an integrity check on the GPU hardware status, loaded database model, and parameters required for the operation of these modules. If an abnormality is detected, it will report to each unit and take corresponding processing measures.

7. The multi-interface compatible intelligent target tracking processing terminal of claim 1, wherein: The touch display screen (2) consists of a display panel, a circuit board, an anti-glare protective glass, and an adjustable outer frame bracket; the display panel uses OLED display; the circuit board includes an image control circuit board and a pixel driving circuit board, and the circuit board is located below the display panel; the anti-glare protective glass covers the display panel; the adjustable outer frame bracket is made of high-strength alloy material; the touch display screen (2) is equipped with a compatible interface, which is connected to the motherboard (3) to receive video signals from external devices and realize multi-source data display.